Isotropic turbulence in compact space
Elias Gravanis, Evangelos Akylas

TL;DR
This paper develops a theoretical framework for studying isotropic turbulence within a compact, periodic space using the Karman-Howarth equation, addressing large-scale effects and realizability issues in turbulence modeling.
Contribution
It introduces a formal theory for isotropic turbulence in a periodic setting, incorporating regularity relations to improve the physical realism of turbulence closures.
Findings
The framework allows consistent investigation of isotropic turbulence models with DNS data.
Regularity relations help maintain physical spectra in the dissipation range.
The approach provides a controllable extension of the inertial range for turbulence analysis.
Abstract
Isotropic turbulence is typically studied numerically through the direct numerical simulations (DNS). The DNS flows are described by the Navier-Stokes equation in a 'box', defined through periodic boundary conditions. The DNS flows live in a compact space and they are not isotropic in their large scales. The investigation of important phenomena of isotropic turbulence, such as anomalous scaling, through the DNS is affected by large scale effects. In this work we put isotropic turbulence - or better, the associated formal theory - in a 'box', through imposing periodicity at the level of the correlations functions. We offer a framework where one may investigate isotropic theories/models through the data of DNS in a formally consistent manner. We work at the level of the Karman-Howarth equation. Unlike the Navier-Stokes equation, infinitely smooth periodicity is obstructed in this theory,…
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